JPH11500216A - Piezoelectric mechanism for gas lighter with nested body closed from outside - Google Patents

Abstract

(57) SUMMARY The present invention comprises a telescoping assembly formed by a first inner body (1A) and a second outer body (2A-2E). The piezoelectric assembly is housed inside and has the piezoelectric ore fixed therein. When struck by the striker hammer (3), the piezoelectric ore is movably guided within the inner telescoping body (1A) and generates a gas ignition spark. The second outer telescoping body (2A-2E) is closed from the outside to prevent intrusion of foreign matter that may cause operational problems of the mechanism. The diametrical projection of the striker (3) comprises a first ramp (25), a second ramp (28), and a longitudinal space (32) in which the outer telescoping body (2A-2E) has a wall-like shape opposed thereto. ). These ramps guide the striker (3) during the assembly process and the activation and resetting of the striker.

Description

DETAILED DESCRIPTION OF THE INVENTION       Piezoelectric mechanism for gas lighter with nested body closed from outside                                 Purpose of the invention   The present invention As stated in the title of this application, Has a remarkable effect compared to conventional products The present invention relates to a piezoelectric mechanism for a gas lighter.   fundamentally, The piezoelectric mechanism used to form the spark A pair of telescoping bodies (teles- copic body) They are mutually supported by springs and extend maximally. Biased to a long position, Means are provided to limit accidental complete separation. One of these bodies To An ore or piezoelectric element that produces a spark when striking Has been established. This piezoelectric element A metal part called "anvil", The part that receives the impact of the striker hammer, or "base" or "stop" Are arranged between the parts to be laid.   The main object of the present invention is to Dust and foreign matter enter the nested parts that house the motion mechanism In order to prevent Provides improved shape of the outer telescoping body structure That is.                                 Background of the Invention   As we all know, In the conventional structure of these piezoelectric mechanisms, The striker hammer enters inward Operates in the axial space of the revolving body, As described below, In the rest position, Holding means Is separated from the piezoelectric element.   To cause ignition, Against the bias of the spring supporting the nested parts , When pressing force is applied to the nested parts manually, Compression of the second spring occurs This is At the moment of being released, the striker hammer operates, As a result, the hammer A collision energy is formed.   The guide means of the striker hammer is Consists of a pair of opposed longitudinal grooves , They are formed along one wall of one tubular body, Striker hammer The two diametrical projections are accommodated.   In the stationary state of the mechanism, Striker hammer Each longitudinal direction of the tubular body In two notches opening at the edge of the groove, Locked by lateral projections Is held. When the striker hammer turns small, Nested parts compression process Escape from the holding notch at the end of During the elongation after the collision, Refit. For this, The protrusion in the diameter direction of the striker hammer is other Move in the window arranged in the telescopic body, Pressed by the edge of the slope of the window You.   US Patent 5, 262, In 697, A mechanism of the aforementioned type is disclosed. In this mechanism Than, Complete guidance of the nested body is achieved. The body is completely geometric Symmetrical and simple structure. The guide means, Return splice for nested parts And The spring that drives the striker hammer and the outside reaching the maximum separation position It can be extended up to. The striker hammer is fully guided during its operation.   This U.S. Pat. 262, The mechanism of 697 is Inductive effect generated at the moment of spark generation Fruit reduction, Position where the outer spring is axially separated from the piezoelectric element It is arranged to occupy. Also, The electric flow of the electric circuit is short, Dried element Negotiations are the least, Using non-conductive resin, Possible to reduce production cost And Prior to the formation of gas ignition sparks, Complete mixing of gas and air Achieve Combustion can be optimized. further, US Patent 5, 262, 697 aircraft The structure is In order to achieve stronger ignition intensity and time, Stop or striker base The intervention of the part ensures that the hammer is completely seated on the piezoelectric element.   In Spanish Patent 890274, A piezoelectric mechanism for gas lighters is described, clay Has been implemented. As a means to reduce the awkward movement between both nested parts, Outside On the body, A pair of protrusions that operate together with the key function are provided. These protrusions Is Grooves in the telescopic body for axial movement of the striker hammer Work within. For this reason, The groove is larger than required for hammer guide Is also required to be long. Current supports striker hammer and nested parts Contrary to the other mechanisms mentioned above, which also flow through the spring, Current is anvil, Piezo required Elementary, It only flows through the stop of the striker hammer and the outer telescoping body The current flow can be shortened.   In a piezoelectric mechanism of the type described above, The spring that supports the striker hammer, Inside the telescopic body that covers the striker hammer, Partially or fully guided , The other end is adjacent to the other end of the cover mounted on the free end of the body. Protrusion Because the part has a saw-tooth part, The protrusions are on each side located on the opposite wall of the telescopic body Inserted into the window, It is fixed at the fixed position.   With a rectangular cross section, House the striker, Diameter protrusion of striker Through the nested body window to guide the Foreign matter, Moisture and dust enter. to this Than, Failure and corrosion of the spring in the telescoping body is caused. Also, Dirty And As a result, For example, the striker that slides in the diameter direction of the striker An increase in friction on the slope occurs. further, Caused by dust and / or moisture Parasitic currents can occur. All of this leads to capacity degradation, point The generation of sparks becomes impossible, as a result, It also causes mechanism blocking. Especially, When the gas valve opens, When blocking occurs, It is a danger.   On the other hand, US Patent 5, 262, 697 and of the type described in EP0172973. During the assembly process of the piezoelectric mechanism, Insert the striker at the diagonal position in the outer telescopic body, The inner telescoping body is inserted such that the outer body penetrates axially. Side struts The beveled slope that allows the squid protrusion to slide, Grooves or longitudinal grooves Until the id reaches Rotate the inner telescoping body slightly.   US Patent 5, 262, 697 and the mechanism of EP0172973, With sufficient results Is the basis of many piezoelectric mechanisms, They are already inserted Position the striker projections diagonally with respect to the And are required, Similarly, During the process of assembling both bodies, It is essential to have an inner end of the inner telescoping body. this is, Complex during the assembly process Accompanied.                                 Summary of the Invention   In order to solve the above-mentioned disadvantages of the known piezoelectric mechanism, The present invention Closed to the outside Provided is a piezoelectric mechanism for a gas lighter having a telescopic body. Conventional outer case The child body is An opening window facing outward is provided, During release and re-equipment, Striker The upper and lower edges of the opening window are inclined so as to form a slope to rotate the hammer Was Instead of this conventional outer telescoping body, Outer nested body like Used. That is, The external telescoping body of the present invention comprises: Closed to the outside, Opposite Two walls are provided with two recesses. The recess is Assembly of double telescoping body During the process and during the release and re-equipment of the striker, Guide the striker protrusion Forming an inclined surface. The upper slope, the first slope, causes refitting, The lower or second slope causes the release.   The piezoelectric mechanism of the present invention, Consisting of first and second telescoping bodies and a first spring , The first spring is Both bodies can be held apart from each other with a certain size And One of the telescoping bodies contains a piezoelectric element. There is no switch inside the other Trica is contained, It is held in the first position and is separated from the piezoelectric element. Sa In addition, The mechanism of the present invention Second spring for biasing striker against piezoelectric element When, Means for preventing relative rotation between the telescoping bodies; Is the striker in the first position Release means.   The means to release the striker are: Related to the nested body. Ie , When enough compressive force is applied, The two bodies move closer to each other, same Sometimes The striker is released from the first position. The second spring strikes As a result of pressing with sufficient force against the piezoelectric element, The impact creates an ignition spark Electrical energy is generated. For this reason, The mechanism is inside the combustion chamber Means for transmitting electrical energy to the electrodes disposed on the first and second electrodes.   The first telescoping body or inner body is Installed between anvil and stop Houses piezoelectric elements. The striker is pressed against the stop.   The second telescoping body or outer body is On the inner wall of the interior space, Guide the striker Slopes, A pair of axial recesses. The striker It is almost cylindrical, No. Means for coupling to the two springs; Guided by the space and slope of the second telescoping body And two lateral projections diametrically opposed to each other.   The means to release the striker Lower slope provided in connection with the recess of the second body That is, the second slope is formed. Nested body moves from one to the other during compression Then The protrusion of the striker contacts the second slope of the recess, First striker From the position. Also, The recess is The compression force is removed and the telescoping body When returning to the rest position, To move the striker protrusion to the first position, Upward Each has a slope, that is, a first slope.   The first telescoping body is A shaft dividing the inner end into two legs having a curved cross section Preferably, a directional groove is provided. It is the axis of the second telescoping body outside Complements the curved portion of the cross section of the through hole. The groove, The inner end of the first telescoping body Extending toward the outside Striker's straightforwardness in release and return of striker It has sufficient travel to allow axial movement of the radial projection.   further, Near the lower end of the first body, Recesses or notches on diametrically opposed edges H is formed. These recesses Position the striker diametrically in the first position The holding means for stopping the device at rest is formed. When the two telescoping bodies are pressed manually , The protrusion contacts the second slope, By sliding this slope, So While they escape from the recess, After the striker releases, The protrusion is Re-enter the recess, The striker is pressed against the first slope and stops at the first position.   According to the present invention, The recess described as relating to the second telescoping body, The second 2 is disposed in the space of the telescoping body or the opposing wall of the axial through hole, Reverse mirror image It is symmetrical.   in this way, The first slope is Two slopes that slope in opposite directions Yes, At a position on the inner surface of the inner space of the second telescoping body on the opposite side in the diameter direction. It is arranged. The slope of each of the two second slopes is at the upper end of the second telescoping body It is inclined toward.   The two second slopes are: Is disposed on the opposite side in the axial direction with respect to the first slope, First oblique It is inclined in the same direction as the surface. Between the end of the first slope and the end of the second slope Is Inevitably parallel, There is a vertical edge, They were released after the striker released 2 During the compression of two nested bodies, as well as, While returning to the stop position, remove the protrusion of the striker. To guide.   The striker's resting position is The protrusion in the diameter direction of the striker is the top of the first slope And the position remaining in the corner formed at the bottom.   In a preferred embodiment according to the present invention, On the opposite inner wall, Axial in the center Splines are formed. This spline starts at one of the ends, Each of the above Terminates in the recess. During assembly, The striker is inserted into the outer telescoping body When done The striker diameter projection Diagonal direction with respect to the internal space of the main body , Or It can be positioned in a direction orthogonal to the spline. the latter in the case of, The free ends of the legs formed on both sides of the longitudinal groove of the inner telescoping body The positioning slope may not be provided. This positioning slope is During assembly, Striker hammer -Is the slope that is rotated. The diametric projection is Guides to longitudinal grooves And When it reaches the holding notch, it rotates again in the opposite direction, The mechanism is at rest.   The general policy is that Improvements incorporating the above mechanism Invariably "tight (tight ) " Foreign molecules or Prevents intrusion of humidity.   For this reason, Two recesses disposed in diametrically opposite regions of the outer telescoping body Indicates the features defined here.   In the axial recess, An upper slope, that is, a first slope, is formed. It is assembled During, as well as, When the compression force is removed and the nested part expands, Inner telescoping body The receiving position is occupied by the lateral notch of the longitudinal groove. As a result, Piezo mechanism early Acquire the rest or return position of the state. Also, In the axial recess, Longitudinal section That is, a vertical edge is formed. that is, During compression and return of nested parts, Strike It determines the limits that allow the longitudinal and rotational movement of the Leica hammer. Finally, In the axial recess, Part 4 defining the lower slope of the space, ie the second slope Minutes are formed. This allows In the final stage of compressing the nested parts The diametric projection escapes, Causes collision with ore. This fourth part Outside It is arranged at the inner end of the cover that covers the lower end of the telescoping body.   The lower slope, the second slope, Installed directly on the inner wall of the outer telescoping body, Forming part of a cover adapted to approach the outer end of the telescoping body; You may do it. A cover with ideal features for the present invention For example, USA Patent 5, 262, 697, It has been disclosed. The contents are Refer to it Is included in the specification of the present invention.   The curvature of the horizontal protrusion of the slope is Matches the fragment of the main circular crown, Outbound It is concentric with the circular cross section of the axial space of the revolving body.   The radius of curvature of the slope of the circular crown fragment is Free of the protrusion on the slope To promote rotation, Larger than the extension between the diametric protrusions of the striker Has become.   In an embodiment of the present invention, The inner space of the outer telescoping body is Lower end of nested part That is, a substantially rectangular cross section extending from the outer end to a substantially horizontal surface of the lower slope, Nesting A substantially circular cross-section extending to the upper end of the interior of the component. in this case, Square of the space The diagonally extending part between each corner of the part, Diagonal through the base of the outer end of the body Can be inserted into Connect the diametrical protrusion of the striker to the upper slope, that is, the second slope. Wide enough to make it movable. in this case, Formed in the first telescoping body The end of the bent leg has a chamfer. This chamfer, During assembly, The first main body rail On the surface of the insertion part of the outer telescopic body, In the second body, the outer telescoping body , As a result of contact with the diametrical protrusion of the striker, Rotate about 45 °, Between legs Facing the protrusion with the groove formed in the Therefore, the projecting portion is fitted with the inner edge of the leg. Id, afterwards, Newly rotated in the opposite direction towards said position, Provided on the leg Cover the protrusion in the side notch.   In another embodiment of the present invention, In the inner space of the second telescopic body, Two vertical switches A pline is formed. This spline is The center of two opposite sides of the inner space Through From the outer end of the second telescoping body to the second slope, ie the plane of the inner slope Extending. Due to the distance between the bases of the two splines, For the second slope Insert and slide the striker, Guide the spline diametrically Can be performed. in this case, End of leg formed in inner telescoping body Is It is not necessary to have a pre-oriented positioning chamber. Because No. When assembling one telescoping body into the second telescoping body, The striker is the above two Forming a rotating motion of Covers in notches formed in the legs of the first telescoping body Because. On the other hand, In this embodiment, Area below the axial penetration of the second telescoping body Is It may be cylindrical, The side region has at least the same width as the first region of the through portion, So It is clear that this space consists of pre-oriented guides and slopes.   In a preferred embodiment of the present invention, Prevent relative rotation between nested bodies Means are provided. this is, US Patent 5, 262, 697 And It is formed by a square "L" -shaped portion.   In the variant, First diagonal of each of two diametrically opposed axial recesses The upper slope, And / or vertical guides or longitudinal edges Formed on an independent part of the outer telescoping body. The independent part is Connect to the rest of the body Is tied.   In a preferred embodiment, A lower slope, a second slope, With a vertical guide Is A cover closing the second body is formed on two opposing wall surfaces. Previous The cover is A tubular portion penetrating through the mouth of the second body. The tubular part At the inner free end of the minute, Two notches are provided on opposite wall surfaces. Of the cover The top is A lower end of a first slope formed on an upper portion of the outer telescoping main body; You.   The lower cover is Has a short neck that penetrates through the lower opening of the body Well, It, along with the notch that forms the lower slope of the space, Include only one on each side Just turn it on.   In another variant, The top of the outer telescoping body is Insert through the upper opening of the remaining part To have a tubular extension to be inserted, It is independent from the rest and can be removed, The Combined with the rest. As well as being oriented for the lower cover, The remaining The side wall of the part In two opposite positions, Coincides with the outside of the tubular extension of the detachable end And a window into which the teeth arranged to be inserted are inserted.   This separation part Above, Independent from the outer telescoping body, Vertical of longitudinal space That is, like the side guide, It is expected to include the first slope, for that reason, Opening The neck that penetrates through the part It is rather long. Because The neck is actually Reaches the inner edge of the lower cover The inner end of the lower cover is in this case, 2nd slope This is because the lower slope is included.   Also, In the present invention, The upper independent portion of the second body has only the first slope, The upper part Has a short length and Its inner mouth reaches the plane where the vertical guide starts, It is also envisioned that the vertical guide is present on the second body with the lower slope. Said Because there is a separable top, The rest of the body consists of a single piece, Opposing length The recess in the hand direction opens at the top.   To better understand the features of the present invention, And to form an integral part of this application , A series of drawings are attached. These drawings are Description and non-limiting features In the meantime, This is described below.                             BRIEF DESCRIPTION OF THE FIGURES   FIG. Prior art More specifically, U.S. Pat. 262, 69 It is a longitudinal elevation view of a gas lighter piezoelectric mechanism corresponding to No. 7, Partially and Located inside the gas lighter body represented in cross section, Indicates the operating state.   FIG. FIG. 1 is a longitudinal elevational view similar to FIG. 1 of a piezoelectric mechanism for a gas lighter according to the invention. And Located inside the gas lighter body, partially and in cross-section, Actuation Indicates the status.   FIG. The length of the second body, the outer telescoping body, according to the first embodiment of the invention It is a direction elevation sectional drawing.   FIG. It is a side elevational view of the internal nesting type | mold main body of a prior art example.   FIG. 1 is a side elevation view of an inner telescoping body according to an embodiment of the present invention.   FIG. FIG. 4 is a sectional view taken along line AA of FIG. 3.   FIG. FIG. 4 is a sectional view taken along line BB of FIG. 3.   FIG. Inserted into the base or inner end of the outer telescoping body of FIGS. FIG. 4 is a side elevational view of a cover according to a conventional example.   FIG. 1 is a side elevational view of an external telescoping body according to the present invention.   FIG. FIG. 4 is a cross-sectional view as viewed from the bottom along line AA in FIG. 3.   FIG. FIG. 5 is a longitudinal sectional view of an external telescopic body according to a second embodiment of the present invention. It is.   FIG. FIG. 12 is a sectional view taken along line C-d of FIG. 11.   FIG. According to a second embodiment inserted into the base of the external telescoping body of FIG. It is a side elevation view of a cover.   FIG. FIG. 5 is a bottom view of the first telescoping body of FIG. 4, ie, the inner telescoping body. .   FIG. FIG. 6 is a bottom view of the inner telescoping body of FIG. 5.   FIG. FIG. 14 is an exploded plan view of the cover shown in FIGS. 8 and 13.   FIG. Longitudinal direction of the outer telescopic body of the piezoelectric mechanism according to the third embodiment of the present invention It is a sectional elevation view, Two members forming the main body are joined.   FIG. FIG. 18 is a longitudinal cross-sectional elevation view of the upper member of the telescoping body of FIG. 17.   FIG. FIG. 19 is a plan view of FIG. 18.   FIG. FIG. 19 is a bottom view of FIG. 18.   FIG. FIG. 19 is a sectional view taken along line DD of FIG. 18.   FIG. Forming the lower member of the outer telescoping body of FIG. 17, External telescoping body FIG. 7 is a longitudinal elevation view of the cover closing from the outside.   FIG. FIG. 23 is a plan view of FIG. 22.   FIG. FIG. 23 is a side elevational view of FIG. 22.   FIG. FIG. 23 is a longitudinal sectional elevation view of the cover of FIG. 22.   FIG. FIG. 18 is a longitudinal sectional elevational view similar to FIG. 17 according to a fourth embodiment of the present invention. You.   FIG. FIG. 27 is a longitudinal sectional elevation view of an intermediate member of the outer telescoping body of FIG. 26. .   FIG. 27 is a longitudinal sectional elevation view of the upper member of the telescoping body of FIG. 26, Above The member is connected to the upper mouth of the central member.   FIG. FIG. 18 is a longitudinal sectional elevational view similar to FIG. 17 according to a fifth embodiment of the present invention. You.   FIG. FIG. 30 is a longitudinal sectional elevation view of the lower member of the outer telescoping body of FIG. 29.   FIG. FIG. 30 is a longitudinal sectional elevation view of the upper member of the external telescoping body of FIG. 29; The upper member is connected to the mouth of the lower member in FIG.                           Description of the preferred embodiment   Referring to FIG. 1 showing an example of the prior art, In this type of piezoelectric mechanism, Inner nesting An expression body, ie a first telescoping body 1, External telescoping body or second telescoping There is a main body 2. They are, Forming a nested assembly, Piezo inside The components of the mechanism are incorporated. These will be described below. State shown in FIG. In The telescoping assembly is assembled and in the park position. Also, Strike The activation mechanism of the Leica 3 has a diametrical projection 4. Symbol 5 is a nested assemble 7 shows a helical spring for returning the rim 1-2 to an extended state.   The inner telescoping body 1 For the external telescoping body 2, Has a tubular cylindrical shape , The striker hammer 3 is guided in it. Diameter of striker hammer 3 The direction projection 4 In each of the longitudinal grooves 6 formed opposite to each other, it freely moves. Longitudinal The direction groove 6 opens at the lower end, Two longitudinal legs 7 are formed. Striker Hammer 3 It is urged by the release spring 8. The release spring 8 In the axial recess of the inner telescoping body 1, And guided inside the external telescoping body 2 You. The lower end of the outer telescoping body 2 contacts the cover 9, The cover 9 is attached to the outside The child type main body 2 is covered.   In the stopped state, The two radial projections 4 of the striker 3 The aforementioned longitudinal legs 7 are housed in the side notches. In this state, Influenced by spring 8 Depending on the pressure The diametric projection 4 is in pressure contact with the upper corner of the return ramp 10. The return ramp 10 As clearly shown in FIG. A point on the opposite wall of the outer telescoping body 2 The upper edge of a symmetrically provided trapezoidal window is formed.   These windows are Said upper return ramp 10; A first vertical portion 11, Release below Ramp 12; Another second vertical portion 13 is formed. Lower corner of window The degree is As can be seen in FIG. It is getting sharp.   Conventional piezoelectric assemblies Seen at the top of the inner telescoping body 1, Real piezoelectric ore Stones, Stand 14, The striker hammer is formed with a stopper part that collides directly I have. Both the base and the ore located in the middle are shown in this figure. Not. The stand 14 Electricity is applied to the first electrode 15 protruding toward the combustion chamber (not shown). Connected. The spark is generated by activation of the push button 16.   on the other hand, The bottom of the outer telescoping body 2 is closed by a cover 9. Cover 9 Are attached by two opposing projections 17. The projection 17 is placed outside. The sub-body 2 is housed in windows 18 on opposite sides of the wall. The release ramp 12 is Instead of being formed on the wall of the body 2, Provided by chamfering the upper end of the cover 9 You may be.   When the piezoelectric mechanism is compressed, The lower part of the main body 1 supports the main body 2 while in the space of the main body 2. Invading, The protrusion 4 is separated from the release ramp 12 and escapes from the notch of the leg 7, release The spring 8 collides with the base of the piezoelectric assembly. Nesting ace While the assembly shrinks, The return spring 5 is compressed. In this state, Put inside The vertical wings of the bent portion 19 forming a part of the slave type main body 1 push the cam 20, The cam 20 opens the gas valve 21. The second ignition electrode 22 can be seen in the gas valve.   When the striker 3 collides with the stopper of the piezoelectric assembly, Electric energy Occurs The electrical energy causes a burst of ignition spark between electrodes 15 and 22. , The gas emitted by the gas valve 21 is ignited. Reference numeral 23 indicates a broken line. It is the outer shell of Iter.   FIG. FIG. Referring to FIG. 7 and FIG. External input of the first embodiment according to the present invention The resilient body is shown at 2A. Lower part of the inner space 24 of the outer telescopic body 2A Has a substantially rectangular cross section (FIG. 7), The upper part has a circular cross section (Fig. 6 ). On the upper internal wall of the main body 2A, There are two diametrically opposed recesses, That A ramp acting on the protrusion of the striker 3 is formed therein. More specifically, The first ramp, the upper ramp 25 and the vertical edges 26 and 27 It is formed. The second ramp, the lower ramp or the release ramp, in this case , It is formed on the edge of the lower cover 9. The cover 9 is provided on the outer telescopic body 2A. The mouth is closed. This lower ramp is shown at 28. Two slopes Roads exist on two opposing walls. further, The lower part of the main body 2A FIG. Like, It has two diametrically opposed windows 18. clearly, The window 18 is It may be replaced with a recess formed in the axial space wall 24 of the telescopic body 2A. No.   As shown in FIG. The lower part of the inner body 1 of the telescoping assembly On its legs 7 , A side notch 29 is provided for receiving the diametric projection 4 of the striker 3. this Figure The leg 7 of the conventional telescopic body 1 of 4 Chamfer 30 is added to the lower end . The function of this chamfer will be described later. In contrast, Internal telescoping body of FIG. 1A does not have such a chamfer.   FIG. FIG. 13 and FIG. The release ramp provided on the cover 9 in other words, the second The ramp or lower ramp 28 is shown in detail. The cover 9 Under the conventional body 2 It is attached to the opening. In the present invention, This is indicated by reference numeral 2A.   FIG. Compared to the conventional external telescoping body 2, External body 2A has conventional window Not As a result, it is shown that it is entirely waterproof.   In FIG. Seeing the return or upper ramp 25 and the axial space 24 Can be. On the outside, The ramp 25 is To form a piece of arc in the cross section To The range is determined by the material of the telescoping body 2A. The arc is Said It is concentric with the circle formed by the cross section of the space 24.   FIG. Except for the external telescoping body, It is the same as FIG. The external telescoping body is Seen laterally close to the outside.   11 and 12, FIG. The most relevant details of the second embodiment of the outer telescoping body 2B It is shown. Striker 3, During the assembly process, Nest its diametric projection If it is placed diagonally with respect to the external base of the formula body, it will not be inserted, Axial space It is inserted through splines 31 formed in the opposite wall of the shaft 24 in the axial direction. This allows It is guided into each facing recess of the telescoping body 2B. these The recess of Vertical edges 26 and 27, Formed by an upper ramp 25 and a lower ramp 28 , Reference numeral 32 indicates. in this case, The striker projection 3 They tilt up Until it reaches the ramp 25 and returns to the stop position, The "orthogonal" state is maintained.   In the embodiment of FIG. The telescoping body 2B is mounted on the window 18 (or the wall of the telescoping body). (A concave portion) that does not completely enter the These windows are External input of the above embodiment It is arranged opposite to the position of the window 18 of the retractable body 2A. Therefore, these Windows are To avoid interference with the spline 31, Nesting without recess 32 It is arranged on the wall of the formula body 2B. Therefore, Cover 9 on telescopic body 2B To install, As shown in FIG. Open ramp or lower ramp 28 On the wall near the location where The mounting projection 17 of the cover 9 is further arranged. You.   According to another embodiment, The axial recess 24 is a complete cylindrical body 2B.   In the embodiment of the telescoping bodies 2A and 2B, Known release and release of striker 3 The operation of the return position It is similar to the operation described in the conventional mechanism of FIG.   To assemble the telescoping mechanism comprising the external telescoping body 2A of the above embodiment Is A conventional internal telescoping body with a chamfer 30 shown in FIGS. 4 and 14 is used. You. In contrast, When handling the nested main body 2B, Figure 5 without chamfer And the telescopic body 1A shown in FIG. 15 may be used unclearly.   In the case of the main body 2A and the striker 3, Release spring 8 and cover 9 are telescopic Assembled on the main body 2A. afterwards, Nesting with piezoelectric elements and the aforementioned bends Expression body 1, The leg 7 surrounded by the return spring 5 of 1A The axial groove 6 So that they are aligned between the recesses 32 It is inserted through the upper base of the telescoping body 2A. When the inner telescoping body 1 is inserted, The chamfer 30 The protrusion 4 of the striker 3 is recessed 32, and are rotated about 45 ° toward the center of 32. That is, Put the protrusion Introduced inside the axial groove 6 of the slave body 1, Housed in notch 29, release The spring 8 rotates reversely by 45 °. Release spring 8 is striker As a result of pushing toward the inner base of the telescopic body, For return of stop position It faces the ramp, that is, the upper ramp 25. This allows Two telescopic bodies 1 , 2A is joined, Form the assembled piezoelectric mechanism.   The outer telescoping body 2B is a conventional inner telescoping body 1, Or as shown in FIGS. 5 and 15 It may be unclearly joined to the telescopic body 1A. When the main bodies 2B and 1 are assembled When The process is substantially the same as the assembly of the main bodies 2A and 1 described above.   When the outer telescoping body 2B and the inner telescoping body 1A are assembled, Return The main body 1A including the return spring 5 and the piezoelectric element The axial groove 6 of the main body 1 is the main body 2B So that the splines 31 First, it is inserted into the main body 2B. This allows Return The return spring 5 is gradually compressed. afterwards, The striker 3 has its diametric projection 4 Is inserted into the inside of the spline 31 of the main body 2D. next, Liberation Pulling was introduced, Finally, the cover 9 is attached. This allows Striker 3 Diametric projection 4 penetrates into axial groove 6 of main body 1A. The cover 9 is assembled Then The release spring 8 is compressed between the cover and the striker. And Body When you stop pushing 1A toward body 2B, The return spring 5 extends, Book Separate bodies 2B and 1A. While the main bodies 1A and 2B are gradually separated, The projection 4 is the main body When it matches the side notch 29 of 1A, The protrusion 4 is pressed by the pressing force of the release spring. And slide on the upper ramp 25, Rotate 45 ° to rotate the notch 29 Is housed inside. In this way, The two telescoping bodies 1A and 2B are connected , The assembled piezoelectric mechanism is formed.   Now 17 and 25, which are other alternative embodiments of the outer telescoping body. When, The outer telescoping body is designated by reference numeral 2C. in this case, External telescoping book The body 2C has an upper ramp 25 formed in each of the opposing concave portions 32. Longitudinal The lower ramp 28 and both side edges of the direction recess 32 are disposed on the cover 9B.   The cylindrical recess of the cover 9B is indicated by reference numeral 33 (FIG. 23). The recess is a nesting book It is housed and guided by the cylindrical inner end of the body 1. Reference numeral 34 guides the release spring 8 A coaxial spigot (spigot) for   FIG. 17 is a longitudinal sectional elevation view of the main body 2C, The lower cover 9B is Join After that, By tooth 17 It is introduced into the corresponding window 18.   In FIG. Return ramp, In other words, A first ramp, namely an upper ramp 25; , An axial space 24 into which the cylindrical part of the upper body 1 is introduced is shown. Figure In 19, The bearing surface of the helical spring 5 for urging the telescopic assembly is denoted by reference numeral 35. It is shown.   In the embodiment shown in FIGS. 26 to 28, The outer telescoping body is generally 2D It is shown. The cross section of the external telescoping body is Over its entire length, Consistent with FIG. doing. At the bottom, The cover 9A is connected. Also, From the upper mouth , A detachable independent member supporting the square neck 37 is connected. Previous The neck 37 is Similar to the engagement of the cover 9A, A window 39 of a main part of the main body 2D; An engaging tooth 38 is provided.   As clearly shown in FIG. Upper ramp 25 and vertical section 26 of longitudinal recess 32 And 27 are formed on a neck 37 of the upper removable portion 36. Downward ramp 2 8 is formed on the upper edge of the lower cover 9A.   Finally, Referring to FIGS. 29 to 31, A fifth embodiment of the present invention is shown. . The outer telescoping body is indicated generally by 2E, Has a removable upper part 40 You. The upper part 40 is The same method as described with respect to the embodiment of FIGS. 26 to 28 By law Locked to the body. However, in this case, Neck or tooth 3 8 support parts, Since it only includes the first ramp or upper ramp 25, Very Has become shorter. The base of the main body 2E is It is formed of a single member. Because The lower part is It doesn't have to be removable, Longitudinal to launch striker The second slope of the direction recess, namely the lower slope 28, With the guide or vertical edge 26 27 is not necessary.   The following is All reference numbers corresponding to elements used in the specification.   1-First telescoping body according to prior art   1A-First telescoping body according to embodiments of the present invention   2- First telescoping body according to prior art   2A-2E-Second telescoping body or external telescoping book according to another embodiment                   body   3-Conventional striker   4-Diameter projection of conventional striker   5- Conventional return spring   6-Longitudinal groove of inner telescoping body 1   7-Longitudinal leg of the inner telescoping body   8-release spring   9-9B-Closure cover for lower opening of telescopic body 2   10—upward return ramp or first ramp   11-Vertical guide   12—Lower release ramp or second ramp   13-Vertical guide   14-units   15-first electrode   16-push button   17-Cover protrusion   18-Complementary window of outer body   19-Bent part integral with the inner telescoping body 1   20-Gas valve opening cam   21-Gas valve   22-second ignition electrode   23-Lighter shell   24-Axial space of external telescoping body   25-Upper ramp of recess to activate and guide striker   26-Vertical edge of recess   27-vertical edge of recess   28-lower ramp of recess   29-side notch of leg 7   30-Chamfering the free end of leg 7   31-Spline of external body 2B   32-recess to activate and guide striker   33-cylindrical recess in cover   34-Coaxial spigot for cover   35-Bearing surface of spring 5   36-Upper Detachable Part of Main Body 2D   37-neck of upper part 36   38-Teeth   39-window   40-Upper Detachable Part of External Telescoping Main Body 2E

────────────────────────────────────────────────── ─── Continuation of front page    (81) Designated countries EP (AT, BE, CH, DE, DK, ES, FI, FR, GB, GR, IE, IT, L U, MC, NL, PT, SE), AU, BG, BR, C A, CN, CZ, GE, HU, IL, JP, KR, LT , MX, NZ, PL, RO, RU, SI, SK, TR, UA, US

Claims (1)

[Claims] 1. A first telescoping body (1, 1A);   A first base into which a first end of the first telescoping body (1, 1A) is inserted; A second base axially opposed to the first base, the first telescopic body having one end A second telescoping body (2, 2A-2E) partially inserted into   In the stop position, the first main body (1, 1A) is connected to the second main body (2, 2A-2). A first spring (5) that is separated from E) by a predetermined interval;   Piezoelectric element housed in any one of the main bodies (1, 1A, 2, 2A-2E) When,   The other axial space (24) of the main body (1, 1A, 2, 2A-2E) In the main body (1, 1A, 2, 2A-2E). It is held at a predetermined distance from the piezoelectric element by the coupled holding means and is diametrically opposed. A substantially cylindrical striker (3) with lateral projections (4);   A second spring (8) for pressing the striker (3) against the piezoelectric element;   Being disposed in the region of the axial space (24) having a trapezoidal square cross section, The striker holding means is functionally complementary and applies a compressive force to the piezoelectric mechanism. The striker connected to the body (1, 1A, 2, 2A-2E). And (3) a striker releasing means for releasing the stop position.   Said telescoping body (1, 1A) comprises an axial groove (6), said groove (6) being Separate the end into two legs (7) and in the groove (6) the diameter of the striker (3) The direction projection (4) is free to move, and the leg (7) is used to hold the side projection. By providing a side notch (29), the striker (3) is guided axially. In the piezoelectric mechanism,   Solution of the telescopic body (2A-2E) in which the striker (3) is housed The release means is disposed inside the second body (2A-2E), and is disposed in the axial space ( 24), two longitudinal recesses (32) formed in opposite mirror images in opposite walls. )   The recess (32)   Towards a stop position at its first end at a first distance from the piezoelectric element An inclined or curved first ramp for guiding the protrusion of the striker (25); When,   A first end adjacent to a first end of the first ramp (25); The strap is moved toward the release position of the second end, which is far away from the piezoelectric element. A straight first axial guide (26) for guiding the squid (3) in the axial direction;   A first end adjacent to a second end of the first ramp (25); 25) while the striker (3) is released to the piezoelectric element. ), A straight second axial guide (27) for guiding the shaft in the axial direction;   Axially opposed to the first ramp (25) and substantially the same as the first ramp (25) Direction, having a curvature equal to the first ramp (25), Activation of the striker (3) to the diametrical projection (4) causes the striker ( Causing the release of 3), A first end adjacent to a second end of the first axial guide (26); A second end adjacent to a second end of the id (27); From the second end of the first axial guide (26), the striker (3) A position axially farthest from the first base of the main body (2A-2E), that is, the second base; Guiding the striker (3) towards the second end of the axial guide (27), A second ramp (28) for release at that position; A piezoelectric mechanism characterized in that the range is defined by: 2. The axial space (24) has a cylindrical first part, the first part being the first part. From the first base of the telescopic body (2A) to the second guide (27) of the recess (32). 3. The method according to claim 1, wherein the second end extends at least to a lateral plane corresponding to the position of the second end. Piezo mechanism. 3. The axial space (24) has a second portion having a rectangular cross section, The two parts are from the horizontal plane to the second base of the second telescoping body (2A, 2B). 3. The piezoelectric mechanism according to claim 2, wherein the piezoelectric mechanism extends. 4. The cross section of the square is a diagonal longer than the diameter of the first part of the cylinder; From the second base of the second telescoping body (2A, 2E) to the striker (3). Have a diagonal line long enough to form a passage through which the diametric projections (4) of the The piezoelectric mechanism according to claim 3, wherein: 5. The axial space (26) has a cylindrical second part with a circular cross section. The second portion extends from the horizontal plane to a second base of the second telescoping body (2B). 3. The piezoelectric mechanism according to claim 2, wherein the piezoelectric mechanism extends. 6. The diameter of the cylindrical second part is the diameter of the cylindrical first part of the axial recess (24). The piezoelectric mechanism according to claim 5, wherein the piezoelectric mechanism is larger than the diameter. 7. The second telescoping body (2B) has two splines (31) in the center wall part. The spline extends from a second base of the outer telescoping body (2B) to the recess. 7. The piezoelectric mechanism according to claim 1, wherein the piezoelectric mechanism extends into (32). 8. The second ramp (28) is provided below the second telescopic body (2A, 2B). Formed in a part of the cover (9) inserted into the axial space (24) of the base, The cross section of the axial space (24) is complementary to the outer cross section of the cover (9). The piezoelectric mechanism according to claim 1, wherein: 9. The surface of the free end of the longitudinal leg (7) is flat. Item 8. The piezoelectric mechanism according to Item 7. 10. The first ramp (25) and / or the axial guide (26, 27) The second telescoping body (2C, 2D, 2E) is formed in a part independent from the second telescoping body (2C, 2D, 2E). The piezoelectric machine according to claim 1, wherein the upright portion is connectable to the rest of the main body. Structure. 11. The axial guides (26, 27), together with the second ramp (28), 2 On the two opposite walls of the cover (9B) that closes the mouth of the main body (2C) from below Formed, said cover comprising a tubular portion, said tubular portion penetrating through said mouth And two notches on the edges of the two opposing side walls, and the upper end of the cover (9B) The device according to claim 10, characterized in that it reaches the lower end of the first ramp (25). Piezoelectric mechanism. 12. The second telescoping body (2D, 2E) has a detachable upper part independent of a lower part. Having a tubular extension (37) inserted through an upper mouth of the lower part. Connected to the lower part, said lower part being provided with mutual locking means (38, 39). The piezoelectric mechanism according to claim 10, wherein: 13. At two opposing positions on the outer surface of the removable upper side wall (36, 40). Teeth (38), the teeth (38) facing opposite windows (3) in the inner side wall of the second body. 13. The piezoelectric mechanism according to claim 12, wherein the piezoelectric mechanism is locked to (9). 14． The independent part (36) above the second telescoping body (2D) is a first ramp ( 25) and a vertical guide (26, 27), the inner opening of which has a cover (9A). Reaching the rim, said cover closing the mouth of the second body (2D) from below and tubular A tubular portion having two notches on its opposite two side edges; 13. This forms a second ramp (28). 14. The piezoelectric mechanism according to any one of 13). 15. The independent part (40) above the telescoping body (2E) comprises a first ramp (2E). 5), the inner opening of which has a guide or longitudinal edge (26, 27), wherein a second ramp (28) is further formed therein. 14. The piezoelectric mechanism according to any one of claims 13 to 13.